Localization of iron-superoxide dismutase in the cyanobiont ofAzolla filiculoides Lam

Summary Immunogold labeling and transmission electron microscopy were used to localize iron-superoxide dismutase (Fe-SOD) in the different cells of nitrogen-fixing cyanobacterial symbiont present within different leaf cavity groups ofAzolla filiculoides Lam. As evidenced by Western blotting and immunoprecipitation, Fe-SOD antibody fromAnabaena cylindrica recognized Fe-SOD in extracts of the cyanobiont and showed the same electrophoretic mobility and pattern as purifiedA. cylindrica Fe-SOD. In vegetative cells of the cyanobiont, Fe-SOD was mainly localized in the thylakoidal membranes and in the outer membrane. The labeling pattern was similar in vegetative cells of the various groups of leaf cavities examined except at the apex where a lower gold particle density was seen. In heterocysts of the leaf cavity groups containing high nitrogenase activity, Fe-SOD labeling was most pronounced and more intense than in vegetative cells. The Fe-SOD label was preferentially located throughout the heterocyst cytoplasm and in the honeycomb regions. In accordance with the decline in nitrogenase activity, the Fe-SOD gold particle density decreased significantly in heterocysts of basal leaf cavity group. The presence of Fe-SOD in regions of high nitrogenase protein levels, and the fact that the pattern of Fe-SOD label parallels that of nitrogenase activity support a role of Fe-SOD in the protection of nitrogenase against superoxide radicals.     

Immunochemical Localization of Nitrogenase in Marine Trichodesmium Aggregates: Relationship to N2 Fixation Potential

Colonial aggregation among nonheterocystous filaments of the planktonic marine cyanobacterium Trichodesmium is known to enhance N₂ fixation, mediated by the O₂-sensitive enzyme complex nitrogenase. Expression of nitrogenase appears linked to the formation of O₂-depleted microzones within aggregated bacterium-associated colonies. While this implies a mechanism by which nonheterocystous N₂ fixation can take place in an oxygenated water column, both the location and regulation of the N₂-fixing apparatus remain unknown. We used an antinitrogenase polyclonal antibody together with postsection immunocolloidal gold staining and transmission electron microscopy to show that (i) virtually all Trichodesmium cells within a colony possessed nitrogenase, (ii) nitrogenase showed no clear intracellular localization, and (iii) certain associated bacteria contained nitrogenase. Our findings emphasize the critical role coloniality plays in regulating nitrogenase expression in nature. We interpret the potential for a large share of Trichodesmium cells to fix N₂ as an opportunistic response to the dynamic nature of the sea state; during quiescent conditions, aggregation and consequent expression of nitrogenase can proceed rapidly.     

Antiserum to Nitrogenase Generated from an Amplified DNA Fragment from Natural Populations of Trichodesmium spp

A fragment of the nifH gene was amplified from natural populations of Trichodesmium spp. and cloned into a maltose-binding protein (MBP) expression vector. The peptide product of the amplified 359-bp fragment of nifH was cleaved from the fusion protein, purified, and used to generate a specific antibody to the Fe protein of nitrogenase. The antiserum recognized the MBP-nitrogenase fusion protein and the cleaved nif peptide product but not MBP. The antibody cross-reacted with nitrogenase from natural populations of Trichodesmium spp. from the Caribbean Sea and with a cultured isolate from the Kuroshio waters (Trichodesmium sp. strain NIBB1067). The same nifH fragment was amplified, cloned, and sequenced from Trichodesmium sp. strain NIBB1067 and was found to be 98% identical at both the protein and DNA levels to nifH from the Caribbean populations. Three of the six nucleotide differences between the Trichodesmium sp. strain NIBB1067 and the Trichodesmium spp. nifH sequence had also been found in a second sequence from the natural populations, indicating either that there is more than one strain of Trichodesmium sp. in natural assemblages or that there are multiple copies of nifH in the genome. This DNA fragment, which is easily amplified with the polymerase chain reaction, may provide a good indicator of species relatedness without requiring extensive cloning or sequencing. Furthermore, the use of the polymerase chain reaction in combination with a MBP protein fusion vector provides a rapid method for production of highly specific sera, starting with a small amount of DNA.     

Whole-Cell Immunolocalization of Nitrogenase in Marine Diazotrophic Cyanobacteria, Trichodesmium spp.

The mechanism by which planktonic marine cyanobacteria of the genus Trichodesmium fix N₂ aerobically during photosynthesis without heterocysts is unknown. As an aid in understanding how these species protect nitrogenase, we have developed an immunofluorescence technique coupled to light microscopy (IF-LM) with which intact cyanobacteria can be immunolabeled and the distribution patterns of nitrogenase and other proteins can be described and semiquantified. Chilled ethanol was used to fix the cells, which were subsequently made permeable to antibodies by using dimethyl sulfoxide. Use of this technique demonstrated that about 3 to 20 cells (mean ± standard deviation, 9 ± 4) consecutively arranged in a Trichodesmium trichome were labeled with the nitrogenase antibody. The nitrogenase-containing cells were distributed more frequently around the center of the trichome and were rarely found at the ends. On average 15% of over 300 randomly encountered cells examined contained nitrogenase. The percentage of nitrogenase-containing cells (nitrogenase index [NI]) in an exponential culture was higher early in the light period than during the rest of the light-dark cycle, while that for a stationary culture was somewhat constant at a lower level throughout the light-dark cycle. The NI was not affected by treatment of the cultures with the photosynthetic inhibitor dichloro 1,3′-dimethyl urea or with low concentrations of ammonium (NH₄Cl). However, incubation of cultures with 0.5 μM NH₄Cl over 2 days reduced the NI. The IF technique combined with ¹⁴C autoradiography showed that the CO₂ fixation rate was lower in nitrogenase-containing cells. The results of the present study suggest that (i) the IF-LM technique may be a useful tool for in situ protein localization in cyanobacteria, (ii) cell differentiation occurs in Trichodesmium and only a small fraction of cells in a colony have the potential to fix nitrogen, (iii) the photosynthetic activity (CO₂ uptake) is reduced if not absent in N₂-fixing cells, and (iv) variation in the NI may be a modulator of nitrogen-fixing activity.     

An analysis of the control of phosphorylation-coupled respiration in isolated plant mitochondria

The control of phosphorylation-coupled respiration in isolated turnip (Brassica rapa) mitochondria was investigated according to the principles of metabolic control analysis as developed by H. Kacser and J. A. Burns ([1973] Symp Soc Exp Biol 32: 65-104) and R. Heinrich and T. A. Rapoport ([1974] Eur J Biochem 42: 97-105). Inhibitor titration studies were used to determine quantitatively the amount of control exerted by four individual processes—cytochrome bc₁, cytochrome oxidase, H⁺-ATPase, and the adenine nucleotide carrier—on respiratory flux under ADP-excess (state 3) and ADP-limited (state 4) conditions with a range of respiratory substrates. Under state 3 conditions control strength was found to be distributed between cytochrome oxidase, cytochrome bc₁, and H⁺-ATPase in decreasing order of importance. The adenine nucleotide carrier exerted no control on respiratory flux under these conditions. Control strength at each step was found to vary with different substrates and with the respiratory flux as altered by ADP supply, i.e. virtually zero control strength at cytochrome oxidase and cytochrome bc₁ under state 4 conditions.     

Impairment of liver regeneration during inhibition of mitochondrial protein synthesis by oxytetracycline

Under standard conditions, liver regeneration is not impaired if mitochondrial protein synthesis is completely blocked. By treating rats with oxytetracycline for various periods of time directly prior to partial hepatectomy, livers were led to a condition of relative deficiency in cytochrome c oxidase and ATP synthetase. To this end, oxytetracycline was administered by means of continuous intravenous infusion up to concentrations of 20 μg/ml serum, giving a gradual decrease in cytochrome c oxidase activity. This activity was used as a marker for functionally capable mitochondria and as a tool to monitor the efficiency of inhibition of mitochondrial protein synthesis. It is shown that liver regeneration is strongly impaired after a period of pretreatment of 22 days or more and continuation of oxytetracycline treatment during regeneration. The mitochondrial respiratory capacity is reduced to 14% of the control value under these conditions. To obtain inhibitory levels within the regenerating liver, it was necessary to raise the serum levels slightly above 20 μg/ml. This measure is most likely required because of the poor vascularization of the regenerating liver. The serum levels were kept, however, far below those known to inhibit cytoplasmic protein synthesis. The results show that in normal liver the respiratory capacity must be reduced drastically before energy-requiring processes become affected. In Zajdela hepatoma cells, similar effects are found after reduction of the cytochrome c oxidase activity to 38%. This difference in sensitivity is probably based on the different mitochondrial content of liver cells and the liver-derived Zajdela cells.     

Reversible coupling of individual phycobiliprotein isoforms during state transitions in the cyanobacterium Trichodesmium analysed by single-cell fluorescence kinetic measurements

In the non-heterocyst, marine cyanobacterium Trichodesmium nitrogen fixation is confined to the photoperiod and occurs coevally with oxygenic photosynthesis although nitrogenase is irreversibly inactivated by oxygen. In previous studies it was found that regulation of photosynthesis for nitrogen fixation involves Mehler reaction and various activity states with reversible coupling of photosynthetic components. We now investigated these activity states in more detail. Spectrally resolved fluorescence kinetic measurements of single cells revealed that they were related to alternate uncoupling and coupling of phycobilisomes from and to the photosystems, changing the effective cross-section of PSII. Therefore, we isolated and purified the phycobiliproteins of Trichodesmium via ion exchange chromatography and recorded their UV/VIS absorption, fluorescence excitation and fluorescence emission spectra. After describing these spectra by mathematical equations via the Gauss-Peak-Spectra method, we used them to deconvolute the in vivo fluorescence spectra of Trichodesmium cells. This revealed that the contribution of different parts of the phycobilisome antenna to fluorescence quenching changed during the daily activity cycle, and that individual phycobiliproteins can be reversibly coupled to the photosystems, while the expression levels of these proteins did not change much during the daily activity cycle. Thus we propose that variable phycobilisome coupling plays a key role in the regulation of photosynthesis for nitrogen fixation in Trichodesmium.     

Light‐dependent oxygen consumption in nitrogen‐fixing cyanobacteria plays a key role in nitrogenase protection1

All colonial diazotrophic cyanobacteria are capable of simultaneously evolving O₂ through oxygenic photosynthesis and fixing nitrogen via nitrogenase. Since nitrogenase is irreversibly inactivated by O₂, accommodation of the two metabolic pathways has led to biochemical and/or structural adaptations that protect the enzyme from O₂. In some species, differentiated cells (heterocysts) are produced within the filaments. PSII is absent in the heterocysts, while PSI activity is maintained. In other, nonheterocystous species, however, a “division of labor” occurs whereby individual cells within a colony appear to ephemerally fix nitrogen while others evolve oxygen. Using membrane inlet mass spectrometry (MIMS) in conjunction with tracer ¹⁸O₂ and inhibitors of photosynthetic and respiratory electron transport, we examined the light dependence of O₂ consumption in Trichodesmium sp. IMS 101, a nonheterocystous, colonial cyanobacterium, and Anabaena flos‐aquae (Lyngb.) Bréb. ex Bornet et Flahault, a heterocystous species. Our results indicate that in both species, intracellular O₂ concentrations are maintained at low levels by the light‐dependent reduction of oxygen via the Mehler reaction. In N₂‐fixing Trichodesmium colonies, Mehler activity can consume ～75% of gross O₂ production, while in Trichodesmium utilizing nitrate, Mehler activity declines and consumes ～10% of gross O₂ production. Moreover, evidence for the coupling between N₂ fixation and Mehler activity was observed in purified heterocysts of Anabaena, where light accelerated O₂ consumption by 3‐fold. Our results suggest that a major role for PSI in N₂‐fixing cyanobacteria is to effectively act as a photon‐catalyzed oxidase, consuming O₂ through pseudocyclic electron transport while simultaneously supplying ATP in both heterocystous and nonheterocystous taxa.     

Effects of a transition from normoxia to anoxia on yeast cytochrome c oxidase and the mitochondrial respiratory chain: Implications for hypoxic gene induction

Previous studies have demonstrated that the mitochondrial respiratory chain and cytochrome c oxidase participate in oxygen sensing and the induction of some hypoxic nuclear genes in eukaryotes. In addition, it has been proposed that mitochondrially-generated reactive oxygen and nitrogen species function as signals in a signaling pathway for the induction of hypoxic genes. To gain insight concerning this pathway, we have looked at changes in the functionality of the yeast respiratory chain as cells experience a shift from normoxia to anoxia. These studies have revealed that yeast cells retain the ability to respire at normoxic levels for up to 4 h after a shift and that the mitochondrial cytochrome levels drop rapidly to 30-50% of their normoxic levels and the turnover rate of cytochrome c oxidase (COX) increases during this shift. The increase in COX turnover rate cannot be explained by replacing the aerobic isoform, Va, of cytochrome c oxidase subunit V with the more active hypoxic isoform, Vb. We have also found that mitochondria retain the ability to respire, albeit at reduced levels, in anoxic cells, indicating that yeast cells maintain a functional mitochondrial respiratory chain in the absence of oxygen. This raises the intriguing possibility that the mitochondrial respiratory chain has a previously unexplored role in anoxic cells and may function with an alternative electron acceptor when oxygen is unavailable.     

Ornithine cycle in Nostoc PCC 73102. Occurrence and localization of ornithine carbamoyl transferase, and the effects of external carbon and ornithine on nitrogenase activity and citrulline synthesis

Cells of free-living nitrogen-fixing Nostoc PCC 73102, a filamentous heterocystous cyanobacterium originally isolated from coralloid roots of the cycad Macrozamia. were examined for the presence of ornithine carbamoyl transferase (OCT) by native-PAGE/in situ activity stain, and SDS-PAGE/Western immunoblots. Transmission electron microscopy and immunocytological labeling were used to study the cellular and subcellular distribution of OCT in the Nostoc cells. Moreover, the effects of photoautotrophic and dark heterotrophic growth metabolism on growth, nitrogenase activity and in vivo citrulline synthesis were investigated. PAGE in combination with in situ activity staining demonstrated an in vitro active OCT with a molecular weight of approximately 80 kDa. SDS-PAGE/Western immunoblots revealed that a polypeptide with a molecular weight of approximately 38 kDa was immunologically related to OCT purified from pea (Pisum sativum L. cv. Alaska). Immunolocalization demonstrated that the OCT protein was located both in vegetative cells and heterocysts. Using the particle analysis of an image processor, the labeling associated with the photosynthetic vegetative cells was calculated to be 75.6 (± 5.5) gold particles μm^?2 compared with 62.0 (± 7.5) in the nitrogen-fixing heterocysts. Glucose and fructose stimulated both cyanobacterial growth and nitrogenase activity in light and darkness. Addition of exogenous ornithine decreased nitrogenase activity. In light grown cells, additions of glucose and fructose in combination with ornithine not only stimulated growth and nitrogenase activity but also in vivo citrulline synthesis, measured as ¹⁴CO₂-fixation into [¹⁴C]-citrulline. In darkness no stimulation was observed on in vivo citrulline synthesis. The substantial stimulation of nitrogenase activity by additions of external glucose and fructose, both in the light and in darkness, was not followed by a simultaneous stimulation of in vivo citrulline synthesis.     

Fusion of phospholipid vesicles reconstituted with cytochromec oxidase and mitochondrial hydrophobic protein

Summary Reconstituted cytochrome oxidase liposomes were fused with liposomes reconstituted with mitochondrial hydrophobic protein, which acts as a membrane-bound uncoupler of cytochrome oxidase. Fusion was assayed by the loss of respiratory control of cytochrome oxidase as measured by the increased rate of ascorbate oxidation induced by hydrophobic protein when both proteins shared the same vesicles. Fusion was dependent on the presence of phosphatidylserine in the liposomes and Ca⁺⁺ in the aqueous medium. Phosphatidylcholine-phosphatidylserine liposomes required higher concentrations of phosphatidylserine and Ca⁺⁺ than did phosphatidylethanolamine-phosphatidylserine liposomes. Cytochrome oxidase vesicles containing high concentrations of phosphatidylserine showed little or no respiratory control, while those with lower concentrations showed high respiratory control; respiratory control could be induced by fusing cytochrome oxidase vesicles containing high phosphatidylserine with protein-free liposomes containing low phosphatidylserine concentration. If cytochrome oxidase vesicles and hydrophobic protein vesicles were prefused separately for 15 min, they lost the ability to fuse upon being subsequently mixed together. The reconstituted vesicles had diameters of about 200 Å; fusion yielded vesicles with diameters in excess of 1000 Å.     

Modeling the Dynamic Regulation of Nitrogen Fixation in the Cyanobacterium Trichodesmium sp.

A physiological, unbalanced model is presented that explicitly describes growth of the marine cyanobacterium Trichodesmium sp. at the expense of N₂ (diazotrophy). The model involves the dynamics of intracellular reserves of carbon and nitrogen and allows the uncoupling of the metabolism of these elements. The results show the transient dynamics of N₂ fixation when combined nitrogen (NO₃⁻, NH₄⁺) is available and the increased rate of N₂ fixation when combined nitrogen is insufficient to cover the demand. The daily N₂ fixation pattern that emerges from the model agrees with measurements of rates of nitrogenase activity in laboratory cultures of Trichodesmium sp. Model simulations explored the influence of irradiance levels and the length of the light period on fixation activity and cellular carbon and nitrogen stoichiometry. Changes in the cellular C/N ratio resulted from allocations of carbon to different cell compartments as demanded by the growth of the organism. The model shows that carbon availability is a simple and efficient mechanism to regulate the balance of carbon and nitrogen fixed (C/N ratio) in filaments of cells. The lowest C/N ratios were obtained when the light regime closely matched nitrogenase dynamics.     

Regulation of nitrogen-fixation by different nitrogen sources in the marine non-heterocystous cyanobacterium Trichodesmium sp. NIBB1067

The effect of various nitrogen sources on the synthesis and activity of nitrogenase was studied in the marine, non-heterocystous cyanobacterium Trichodesmium sp. NIBB1067 grown under defined culture conditions. Cells grown with N₂ as the sole inorganic nitrogen source showed light-dependent nitrogenase activity (acetylene reduction). Nitrogenase activity in cells grown on N₂ was not suppressed after 7 h incubation with 2 mM NaNO₃ or 0.02 mM NH₄Cl. However, after 3 h of exposure to 0.5 mM of urea, nitrogenase was inactivated. Cells grown in medium containing 2 mM NaNO₃, 0.5 mM urea or 0.02 mM NH₄Cl completely lacked the ability to reduce acetylene. Western immunoblots tested with polyclonal antisera against the Fe-protein and the Mo–Fe protein, revealed the following: (1) both the Fe-protein and the Mo–Fe protein were synthesized in cells grown with N₂ as well as in cells grown with NaNO₃ or low concentration of NH₄Cl; (2) two bands (apparent molecular mass of 38 000 and 40 000) which cross-reacted with the antiserum to the Fe-protein, were found in nitrogen-fixing cells; (3) only one protein band, corresponding to the high molecular mass form of the Fe-protein, was found in cells grown with NaNO₃ or low concentration of NH₄Cl; (4) neither the Fe-protein nor the Mo–Fe protein was found in cells grown with urea; (5) the apparent molecular mass of the Fe-protein of Trichodesmium sp. NIBB1067 was about 5000 dalton higher than that of the heterocystous cyanobacterium, Anabaena cylindrica IAM-M1.     

Isolation and purification of the cytochrome oxidase of Azotobacter vinelandii

A membrane-bound cytochrome oxidase from Azobacter vinelandii was purified 20-fold using a detergent-solubilization procedure. Activity was monitored using an ascorbate-TMPD oxidation assay. The oxidase was ‘solubilized’ from a sonic-type electron-transport particle (R₃ fraction) using Triton X-100 and deoxycholate. Low detergent concentrations first solubilized the flavoprotein oxidoreductases, then higher concentrations of Triton X-100 and KCl solubilized the oxidase, which was precipitated at 27–70% (NH₄)₂SO₄. The highly purified cytochrome oxidase has a V of 60–78 μgatom O consumed/min per mg protein. TMPD oxidation by the purified enzyme was inhibited by CO, KCN, NaN₃ and NH₂OH; NaNO₂ (but not NaNO₃) also had a potent inhibitory effect. Spectral analyses revealed two major hemoproteins, the c-type cytochrome c₄ and cytochrome o; cytochromes a₁ and d were not detected. The Azotobacter cytochrome oxidase is an integrated cytochrome c₄?o complex, TMPD-dependent cytochrome oxidase activity being highest in preparations having a high c-type cytochrome content. This TMPD-dependent cytochrome oxidase serves as a major oxygen-activation site for the A. vinelandii respiratory chain. It appears functionally analogous to cytochrome a+a₃ oxidase of mammalian mitochondria.     

Ca2+ transport against its electrochemical gradient in cytochrome oxidase vesicles reconstituted with mitochondrial hydrophobic proteins

Cytochrome oxidase vesicles have recently been shown to accumulate Ca²⁺ in an energy-dependent manner. Energization of these vesicles with internally trapped cytochrome c and externally added ascorbate and phenazine methylsulfate generated an internally positive membrane potential and prevented Ca²⁺ influx (R. N. Rosier and T. E. Gunter, 1980, FEBS Lett.109, 99–103). In contradistinction, when cytochrome oxidase vesicles were reconstituted with complex V, a mitochondrial protein fraction containing the uncoupler binding site (Y. Hatefi, D. L. Stiggall, Y. Galante and W. G. Hanstein, 1974, Biochem. Biophys. Res. Commun.61, 313–321), both Ca²⁺ uptake and generation of an internally positive membrane potential were observed. The uptake was specifically dependent on energization of electron transport. Control experiments verified that the energization conditions used produced appropriately oriented membrane potentials. Other partially purified hydrophobic mitochondrial protein complexes were found to be less effective than complex V. The reconstituted system showed cation selectivity since Ca²⁺, Mn²⁺, and Rb⁺ were transported, while Na⁺ was not. Low levels of uncoupler, which did not affect oxidation rates, were found to partially inhibit Ca²⁺ uptake regardless of the membrane potential polarity. Uncoupling levels of uncoupler markedly inhibited Ca²⁺ uptake in internally negative cytochrome oxidase vesicles; however, inhibition in internally positive cytochrome oxidase vesicles was less relative to that at lower levels of uncoupler. The uncoupling combination of nigericin, valinomycin, and K⁺ was inhibitory to uptake regardless of membrane potential polarity. A reconstituted system of oxidative phosphorylation, which contains a hydrophobic protein fraction, energized with cytochrome oxidase similarly accumulated Ca²⁺ despite formation of an internally positive membrane potential. The results suggest that cytochrome oxidase, when coupled to appropriate hydrophobic mitochondrial proteins, can act as an electrogenic Ca²⁺ pump deriving its energy directly from electron transport.     

Increased Respiration Through Cytochrome d Enhances Microaerobic N2Fixation in Klebsiella Pneumoniae

Nitrogenase activity was increased in a Klebsiella pneumoniae strain (FN27) producing higher amounts of cytochrome d than the wild-type strain. The increased production of cytochrome d in FN27 showed a positive effect on nitrogenase activity in cells cultured with glucose as carbon source at 1 kPa oxygen but a negative effect at higher O₂concentrations. In cells cultured with pyruvate as carbon source, FN27 expressed higher activity of nitrogenase at all oxygen tensions tested when compared to the wild-type strain. This analysis shows that the over production of cytochrome d terminal oxidase improves nitrogen fixation in certain culture conditions.